Contrasting Carbon Growth from Ethane and Ethylene

metal-support interface during initial stages of carbon deposition from light hydrocarbons over model Ni/CeO2 .... metal-support interactions on C-H b...
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Article Cite This: ACS Appl. Nano Mater. 2018, 1, 1360−1369

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Oxygen Transfer at Metal-Reducible Oxide Nanocatalyst Interfaces: Contrasting Carbon Growth from Ethane and Ethylene Ethan L. Lawrence and Peter A. Crozier* School for the Engineering of Matter, Transport and Energy, Arizona State University, 501 E. Tyler Mall, Tempe, Arizona 85287-6106, United States S Supporting Information *

ABSTRACT: Carbon deposition from hydrocarbon gases onto metal nanoparticles is an important process impacting materials synthesis and catalysis. Typically, light hydrocarbons may decompose on metal nanoparticles resulting in the formation of graphene layers and hydrogen gas. During hydrocarbon reforming, hydrocarbons are converted to syngas (CO and H2), and carbon deposition is an undesirable side reaction, which can deactivate the catalyst and cause mechanical degradation. Here, aberration-corrected in situ environmental transmission electron microscopy (ETEM) was employed to investigate the atomiclevel three-phase interactions occurring at the metal−support interface during the initial stages of carbon deposition from light hydrocarbons over model Ni/CeO2 and Ni/SiO2 catalysts. During exposure to C2H6, no carbon deposition took place, and localized reduction zones at the metal−CeO2 interface demonstrated a carbon oxidation mechanism. In contrast, during exposure to C2H4, carbon deposition occurred and was associated with less pronounced reduction zones. The metal−support interface can catalyze the oxidative dehydrogenation of C2H6 and subsequently oxidize the resulting carbonaceous species. For C2H4, rapid dehydrogenation occurs directly on the Ni surface, which also catalyzes graphite formation. These experiments demonstrate that the ability of interfacial oxygen to inhibit carbon deposition during reforming is strongly influenced by thermodynamic and kinetic considerations, which may show significant variation among different hydrocarbon species. KEYWORDS: Ni reforming catalyst, CeO2, metal-oxide interface, in situ TEM, carbon deposition, hydrocarbon fuel, carbon oxidation

1. INTRODUCTION Carbon deposition from hydrocarbon gases onto metal nanoparticles is an important process impacting materials synthesis and catalysis. Typically, light hydrocarbons may decompose on metal nanoparticles resulting in the formation of graphene layers and hydrogen gas. This process can be exploited to fabricate nanomaterials such as graphene and carbon nanotubes.1−3 During hydrocarbon reforming, hydrocarbons are converted to syngas (CO and H2), and carbon deposition is an undesirable side reaction, which can deactivate the catalyst and cause mechanical degradation. For example, during direct reforming on solid oxide fuel cell (SOFC) anodes, carbon deposition not only deactivates the catalyst but also may fracture or destroy the anode microstructure if not controlled.4−6 Nickel, in the form of nanoparticles, is often employed as the catalyst for hydrocarbon reforming because of its ability to activate the C−H bond and its low cost. For processes such as steam reforming, dry reforming, or partial oxidation, the oxidizing reactant is introduced to the reactor in gaseous form (H2O, CO2, or O2), which adsorbs and dissociates on the catalyst surface.7,8 For reforming on SOFC anodes, the oxidizing reactant is reactive lattice oxygen, which diffuses through the fuel cell from the cathode. Any restriction in access or decrease in supply of oxidizing reactants may result in carbon formation and subsequent degradation. © 2018 American Chemical Society

It is desirable to look for materials systems that inhibit carbon deposition while promoting reforming activity. Carbon deposition is always possible during dehydrogenation of hydrocarbons, so a bifunctional composite catalyst, which offers one set of sites that are effective at activating C−H bonds and a separate set of sites that can oxidize carbon species may be necessary. Metal catalysts supported on reducible oxides can provide this bifunctionality, since the metal surface will activate the hydrocarbon, and the oxide may be effective for the oxidation of carbon.9 In such metal−ceramic composite systems, interfacial interactions are critical in controlling the chemical reactions occurring on the material’s surface. Metal supported on ceria (CeO2)-based materials are examples of such interfacial systems that show high catalytic activity for CO and hydrocarbon oxidation reactions10 and are known to inhibit carbon deposition by oxidizing carbon on their surface with oxygen from their lattice.11 The use of Ni/ceria-based catalysts has provided improved carbon-resistant systems for industrial steam reforming, dry reforming, partial oxidation, and autothermal reforming processes due to the high oxygen mobility introduced by the ceria component.12−14 For fuel cell Received: January 18, 2018 Accepted: March 7, 2018 Published: March 7, 2018 1360

DOI: 10.1021/acsanm.8b00102 ACS Appl. Nano Mater. 2018, 1, 1360−1369

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ACS Applied Nano Materials

Figure 1. Typical images of fresh catalysts in 4 Torr H2 at 400 °C. (a) Ni/GDC, (b) Ni/CeO2, (c) Ni/SiO2.

applications, doping ceria with a trivalent cation, such as Gd3+, yields a material with higher oxygen ionic conductivity at intermediate temperatures.15 The addition of Ni particles to doped ceria improves the electrocatalytic activity and produces a promising internal reforming anode material: during reforming, Ni catalyzes the decomposition of hydrocarbon fuel molecules, and the doped ceria enables the fast transport of oxygen from the bulk oxide lattice to the surface, to oxidize adsorbed carbon to CO or CO2. Despite Ni/ceria-based catalysts exhibiting improved carbon resistance, the literature on reforming light hydrocarbon components of important feedstocks, such as natural gas, over Ni/ceria-based catalysts lacks comparative analysis of carbon formation from different hydrocarbons. Most studies have focused on methane (CH4) reforming to syngas, since CH4 is the predominant component of natural gas.16−22 For example, Liu et al. investigated the effects of metal−support interactions on C−H bond breaking for dry reforming of methane over a Ni/CeO2 catalyst.22 However, to obtain a more complete picture of carbon deposition associated with natural gas and metal-oxide interfacial processes, it is important to investigate the behavior of higher hydrocarbons, such as ethane (C2H6) and propane (C3H8). Recently, a few studies have examined the carbon formation processes associated with ethane and propane reforming over various catalysts.5,23−26 The deposition of carbon from these gases has been shown to occur more easily than from methane,5,27−29 making their behavior of paramount importance. To understand differences in the carbon deposition behavior, it is important to characterize the interactions that take place at the metal-oxide interface. In many reactions over reducible oxides in the presence of molecular O2, oxidation occurs via a Mars−van Krevelen redox mechanism, in which lattice oxygen transfers to an adsorbate species, creating an oxygen vacancy on the surface. This is followed by the reduction of molecular O2 on the surface and filling of the oxygen vacancy, which restores the surface for subsequent catalytic cycles. In the absence of molecular O2, the oxygen vacancy may be filled using adsorbed H2O or CO2 or via vacancy migration away from the surface into the bulk. The rate at which adsorbates are oxidized at the metal-oxide interface depends on the concentration of adsorbate species at the interface and the oxygen vacancy formation energy at the three-phase boundary, i.e., line of contact between the gas phase, the metal, and the oxide. Ceria has a high oxygen storage capacity and will serve as an oxygen source during initial oxidation reactions on the surface. Moreover, it is also a fast oxygen ion conductor, and it may be initially easier to backfill the surface oxygen vacancy by oxygen migration from the lattice rather than the potentially

more difficult four electron transfer process required for the dissociation of a molecular O2 adsorbate.30 However, after oxygen is depleted from the outer layers of the crystal, molecular dissociation of reactant species may become more favorable due to the large distance that lattice oxygen must diffuse from the crystal interior. In situ studies, which directly probe the metal-oxide interface evolution in the presence of different hydrocarbons, may provide valuable insights on the atomic-level mechanism leading to carbon formation.31 Advances in aberrationcorrected, in situ environmental transmission electron microscopy (ETEM) have enabled such an understanding by providing atomic-scale catalyst characterization under nearreaction conditions.32−35 For example, in situ ETEM has been used to investigate atomic-level nucleation and growth mechanisms of carbon nanotubes over Ni catalysts.36−39 Additionally, Kling et al. directly observed graphene layer formation on Ni nanoparticles using in situ ETEM and were able to determine local growth rates of graphene as a function of gas pressure in the ETEM cell.40 When complemented with electron energy-loss spectroscopy (EELS) and scanning TEM (STEM) capabilities, in situ ETEM allows insights into the atomic-level mechanisms taking place at the metal-oxide interface during carbon deposition processes. In the present study, we have employed ex situ characterization and aberration-corrected, in situ ETEM techniques to investigate the atomic-level metal−support interactions occurring during the initial stages of carbon deposition from light hydrocarbons over model Ni reforming catalysts. To determine speciesdependent differences in carbon deposition behaviors, representative natural gas species were reformed separately, and the amount of carbon deposited by each species was quantified. A model Ni/CeO2 nanocube catalyst system was chosen to facilitate the interpretation of in situ ETEM experiments. To elucidate the role of the reducible oxide on regulating carbon deposition from light hydrocarbons, the same ex situ and in situ experiments were performed on an Ni catalyst supported on SiO2, a nonreducible oxide. As a reducible oxide, CeO2 can contribute oxygen to its surroundings with an accompanied reduction of the Ce oxidation state from Ce4+ to Ce3+. The Ce oxidation state can be monitored with EELS41 and, when combined with STEM, can provide nanometer level resolution; thus, local structural evolution can be correlated with catalytic properties under working conditions. Here, we acquire in situ atomic-resolution TEM images and STEM/ EELS line scans of the catalyst particles and interfaces to identify the mechanisms that enable Ni/CeO2-based catalysts to inhibit carbon deposition from light hydrocarbons. The primary focus of the current work is exploring the fundamental 1361

DOI: 10.1021/acsanm.8b00102 ACS Appl. Nano Mater. 2018, 1, 1360−1369

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ACS Applied Nano Materials

Figure 2. (a) Conversion data for partial oxidation of methane and partial oxidation of ethane over Ni/GDC catalyst. The ethane reforming reaction proceeded at lower temperatures than methane reforming. Carbon deposits were observed after ethane reforming but not after methane reforming. (b) Carbon-containing products present during C2H6 reforming reaction. reforming and carbon deposition experiments. For ex situ reforming experiments, the input reactant gas was a mixture of CH4/O2/He or C2H6/O2/He, with typical flow rates of 8 cc/min of C2H6 or C2H4, 4 cc/min of O2, and 50 cc/min of He. The catalyst bed temperature was increased from 30 to 900 °C at a rate of ∼4 °C/min, and the conversion of fuel to products was monitored as a function of temperature. For ex situ carbon deposition experiments, the Ni-supported catalysts were first reduced at 400 °C for 2 h in 5% H2/Ar and then heated to 550 °C in 5% H2/Ar at a heating rate of ∼4 °C/min. At 550 °C, the catalyst was exposed for 10 min to a hydrocarbon gas present in natural gas or observed during reforming. To quantify the amount of carbon deposited during the reaction, temperature-programmed oxidation (TPO) was carried out by flowing 50 cc/min of He and 3 cc/min of O2 while heating to 750 °C at a rate of 2 °C/min. The deposited carbon was oxidized to CO2, and the resulting output gas flow was analyzed using a Varian 3900 GC. A JEOL 2010F TEM was used to image all ex situ carbon deposition catalysts. 2.3. In Situ Catalyst Characterization. In situ electron microscopy experiments were undertaken to obtain a deeper understanding of the relationship between the carbon deposition process, the oxide support, and the hydrocarbon source. The experiments were performed on an FEI Titan ETEM equipped with a Gatan Imaging Filter (GIF), which was used for EELS. For all experiments, Ni/SiO2 and Ni/CeO2 powders were dispersed onto a Pt mesh TEM sample grid and loaded into a Gatan hot stage. The catalysts were initially reduced at 400 °C for 2 h in 5% H2/Ar in an ISRI RIG-150 microreactor. The sample was transferred to the FEI Titan ETEM and further reduced in situ at 400 °C for 2 h in 4 Torr H2 to remove any surface oxides that may have formed during transfer to the microscope. Regions of interest were imaged in H2, and the sample was cooled to 100 °C. Hydrocarbon gas was then introduced to the sample chamber, heated to 550 °C, and the same regions were imaged as in H2. Images were acquired over 1−4 h of hydrocarbon exposure. Under real internal reforming conditions of a SOFC, H2O and CO2 will also be present on the anode. However, it is important to recognize that the reforming conditions will be very different along the anode flow channel.47 Close to the inlet, the concentration of H2O and CO2 will be very low, whereas at the outlet, these products will dominate.48 Thus, we anticipate that the conditions present in the ETEM would be close to those present at the anode inlet. For in situ STEM experiments, a nominal probe size of ∼2 Å was used; however, in practice, instabilities in both the hot stage and sample at elevated temperature degraded the spatial resolution of the spectroscopy up to 1 nm, although this did not impact the overall conclusions from the analysis. In situ EELS was used to monitor the oxidation state of Ce3+, which varies with the oxygen content of the 4+ ceria according to Ce3+ x Ce1−xO2−x/2. Transitions from the occupied 5/2 3/2 3d band and the 3d band to unoccupied 4f states above the Fermi level give rise to sharp spectral peaks at 879 eV (M5) and 900 eV (M4), the so-called Ce M45 edge. The occupancy of the 4f band changes from

carbon formation behavior taking place under conditions when gaseous oxygen is not readily available (i.e., a solid oxide fuel cell anode). While the activity of the coked catalyst for reforming was not determined, we anticipate that similar carbon deposition would eventually deactivate the catalyst.21,42

2. EXPERIMENTAL SECTION 2.1. Catalyst Synthesis. A 20 wt % Ni/Gd0.15Ce0.85O2 powder was synthesized using a one-step spray-drying synthesis technique.43 Precursors of Ni(NO3)2·6H2O, Ce(NO3)3·6H2O, and Gd(NO3)3· 6H2O (Alpha Aesar, Ward Hill, MA), all of at least 99.99% purity, were combined in appropriate amounts to form a 0.1 M aqueous solution. The solution was sprayed into a stream of hot air (∼300 °C) to produce a powder of nanoparticles. As recommended by Sharma et al., the resulting powder was calcined at 700 °C for 2 h to facilitate nitrate decomposition and NiO/GDC nanoparticle formation.43 A subsequent reduction in H2 at 400 °C was necessary to convert NiO/GDC into the catalytically active phase of interest, Ni/GDC, which is seen in Figure 1a. CeO2 cubes were synthesized by the method developed by Yang et al.44,45 In a typical synthesis, Ce(NO3)3·6H2O was dissolved into distilled water and mixed with a 12 M NaOH solution for 30 min with stirring. The resulting slurry was placed into a 50 mL autoclave and heated to 200 °C for 24 h. The precipitate was isolated by centrifugation, washed multiple times with deionized water, and dried at 60 °C overnight in air. A wet-impregnation technique was used to deposit 10 wt % Ni onto the CeO2 cubes. An appropriate mass of Ni(NO3)2·6H2O was dissolved in ethanol and mixed with CeO2 cubes in a saturated ethanol environment to form a slurry. After the slurry was mixed for 30 min in the ethanol environment, it was dried at 60 °C in air for 2 h to yield a powder, which was calcined at 350 °C for 2 h. The resulting Ni/CeO2 catalyst yielded an average Ni particle size of 8.6 nm. A typical Ni/CeO2 cube catalyst is shown in Figure 1b following NiO reduction. Amorphous SiO2 spheres were synthesized via the Stöber method.46 The resulting powder was collected and calcined at 500 °C for 2 h. The resulting amorphous silica spheres were impregnated with 7.3 wt % Ni using the same wet-impregnation recipe as described in Chenna et al.47 A 7.3 wt % Ni loading was chosen due to a nearly identical particle size distribution to the 10 wt % Ni/CeO2 catalyst; the average Ni particle size on the 7.3 wt % Ni/SiO2 catalyst was 8.9 nm. The resulting Ni/SiO2 catalyst is shown in Figure 1c after NiO reduction. 2.2. Ex Situ Catalyst Characterization. The freshly calcined catalysts’ activity for the catalytic partial oxidation of methane to syngas (CH4 + 1/2O2 → CO + 2H2) was determined using an In Situ Research Instruments (ISRI) RIG-150 microreactor with a 10 mm internal diameter quartz tubular fixed-bed flow furnace. Under similar experimental conditions, the activity for the catalytic partial oxidation of ethane was determined. Product gases were analyzed with a Varian 3900 Gas Chromatograph (GC). This system was used for all ex situ 1362

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Figure 3. Ex situ carbon deposition from ethylene (C2H4) on Ni/SiO2 and Ni/CeO2. A large amount of carbon nanofibers grew on Ni/SiO2 as seen in (a). Carbon deposited in the form of graphite onto Ni/CeO2. (b) shows a Ni particle that was encapsulated with graphite during C2H4 exposure. (c) Temperature-programmed oxidation results from C2H4 onto model Ni/CeO2 and Ni/SiO2 catalysts. Ni/CeO2 was unable to inhibit carbon deposition as evidenced by the peak at ∼425 °C in the red dotted line. 0 to 1, as the oxidation state of Ce changes from 4+ to 3+. A simple method to determine the occupancy of the 4f states is to use the relative intensity ratio of the M5 and M4 peaks.41 We used an assumption that the M5-to-M4 intensity ratio measured at room temperature in vacuum represented the Ce4+ state, while the intensity ratio measured at 800 °C in H2 represented a Ce3+ oxidation state. Values between these two limiting values represent a mixture of Ce4+ and Ce3+ oxidation states. All experimental data were quantified assuming a linear relationship between the M5-to-M4 intensity ratio and the Ce oxidation state. The local Ce oxidation state, and thus the local oxygen content of the ceria support, was determined. Spectra were acquired over 1−4 h of hydrocarbon exposure.

temperatures and were the focus for ex situ carbon deposition experiments. 3.2. Ex Situ Carbon Deposition. The carbon deposition observed following C2H6 reforming may have been deposited by the reactants, products, and/or intermediate gas species present at the surface of the Ni/GDC catalyst. To determine the carbon species most likely to cause carbon deposition, a set of experiments was performed to quantify the amount of carbon deposited individually by each of these gases: C2H6, C2H4, CH4, and CO. The Ni/GDC catalyst was heated to 550 °C, a temperature at which all four carbon-containing gases were observed during the C2H6 reforming experiment, in an ISRI RIG-150 microreactor and exposed to each of the four carbon-containing gases separately under conditions specified previously in the Experimental Section. The TPO results are summarized in Figure S1, and it is shown that C2H4 is responsible for the largest amount of deposited carbon as evidenced by the largest peak. C2H6 was responsible for the second largest amount. CO deposited a minimal amount of carbon under these conditions. CH4 also showed minimal carbon deposition when compared to C2H4 and C2H6. These observations are consistent with prior work showing that twocarbon molecules deposit carbon more easily than CH4,5,27−29 further underscoring the need to evaluate the performance of catalysts under representative light hydrocarbon environments. Thus, C2H4 and C2H6 were selected for further investigation of carbon deposition behaviors onto model Ni/CeO2 and Ni/ SiO2 systems. To determine the differences in carbon deposition behaviors between C2H4 and C2H6, ex situ carbon deposition experiments were performed using model Ni/CeO2 and Ni/SiO2 catalysts. The Ni/CeO2 and Ni/SiO2 catalysts were heated to 550 °C and exposed to either C2H6 or C2H4 for 10 min. Following cool down, the catalysts were examined with a JEOL 2010F TEM. Ni particles reoxidized to NiO during transfer to the microscope. Many carbon nanofibers (CNFs) were observed on the Ni/SiO2 catalyst when exposed to C2H4 as is seen in Figure 3a. The growth of CNFs is consistent with other studies on Ni/SiO2 and C2H4 exposure.49 Graphite growth was observed on Ni/CeO2 during C2H4 exposure, and some Ni particles were encapsulated with graphite, as shown in Figure 3b. Ceria surfaces were void of graphite; only Ni particle surfaces showed carbon. TPO was performed to quantify the amount of carbon present on the model Ni/CeO2 and Ni/SiO2

3. RESULTS 3.1. Catalytic Activity of Reforming Reactions. The partial oxidation of methane to syngas (CH4 + 1/2 O2 → CO + 2H2) over a Ni/GDC catalyst was investigated from 100 to 900 °C. As seen in Figure 2a, CH4 and O2 conversion began around 350 °C and produced CO2 and H2O (complete oxidation of methane) until ∼700 °C. At 700 °C, O2 conversion reached 100%, and a significant increase in CH4 conversion occurred. This large increase in CH4 conversion has been discussed previously47 and is attributed to NiO particles converting to Ni metal once a reducing environment has been established by complete O2 conversion. Once reduced to Ni, the catalyst produced CO and H2 (partial oxidation of methane), and for the reactor conditions employed here, it showed methane conversion that was near thermodynamic limits. The partial oxidation of ethane was also investigated over a Ni/GDC catalyst from 100 to 900 °C. Conversion results are also shown in Figure 2a. C2H6 and O2 began converting at roughly the same temperature (350 °C) as CH4 and O2 reforming. During C2H6 reforming, the O2 conversion reached 100% at 600 °C, and a significant increase in C2H6 conversion occurred. This significant increase in conversion can again be associated with the conversion of NiO to Ni. Complete C2H6 conversion occurred around ∼700 °C, while CH4 was not fully reformed until ∼800 °C. Notably, carbon deposits (graphite layers) were observed with TEM on the catalyst following C2H6 reforming but not after CH4 reforming. Thus, reactions occurring with gases present during C2H6 reforming caused carbon deposition onto the Ni/GDC catalyst. Figure 2b shows the carbon-containing products detected during the partial oxidation of ethane. Ethylene (C2H4), CH4, CO, CO2, and residual unreformed C2H6 were all detected at various 1363

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Figure 4. Ex situ carbon deposition from ethane (C2H6) on Ni/SiO2 and Ni/CeO2. Carbon nanofibers grew on Ni/SiO2 as seen in (a). No carbon deposition was observed on Ni/CeO2. Ni particle surfaces were clean when supported by CeO2 as seen in (b). (c) Temperature-programmed oxidation results from carbon deposited during C2H6 exposure on Ni/SiO2, Ni/CeO2, SiO2, and CeO2. SiO2 and CeO2 had no carbon deposits. Ni/ CeO2 had a minimal amount of deposited carbon compared to Ni/SiO2.

catalysts. TPO results in Figure 3c show that large carbon deposits were on Ni/SiO2 (solid blue line) relative to Ni/CeO2 (dotted red line), likely due to the large number of CNFs present on Ni/SiO2. Thus, carbon deposition occurred on both Ni/SiO2 and Ni/CeO2, indicating that the CeO2 support was unable to inhibit carbon deposition during C2H4 exposure. During C2H6 exposure, all Ni/SiO2 particles showed a large degree of CNF growth as seen in Figure 4a, but no CNFs were observed on any Ni/CeO2 catalyst (Figure 4b). TPO was also used to quantify the deposited carbon from C2H6 onto each catalyst; results are shown in Figure 4c. Additionally, each bare support was subjected to the same hydrocarbon conditions, and the TPO results are included in Figure 4c. Bare SiO2 and CeO2 had no carbon deposits as evidenced by the lack of peaks in the TPO results. The lack of carbon deposition on the bare supports is consistent with other studies that have examined carbon deposition on these supports, which concluded that Ni is necessary to catalyze hydrocarbon decomposition.50,51 As evidenced by the largest peak in Figure 4c, Ni/SiO2 had a large amount of carbon deposition when compared to the very small peak from Ni/CeO2. The comparison of Ni on these two different supports suggests that the metal−support interaction between Ni and CeO2 plays a key role in suppressing carbon deposition onto the Ni/CeO2 catalyst during C2H6 exposure. 3.3. In Situ Carbon Deposition. In situ ETEM experiments were conducted to investigate the differences in carbon deposition behaviors between C2H4 and C2H6 exposure during reaction conditions. Initial images were recorded in an H2 environment to ensure NiO particles had been reduced to Ni and to have baseline structural information to facilitate the identification of changes induced by hydrocarbon introduction. Figure 5a,b shows an Ni/SiO2 particle at 400 °C in 4 Torr H2 and 550 °C in 0.5 Torr C2H4, respectively. Graphite layers were seen growing on the Ni surface during C2H4 exposure. Likewise, graphite layers formed on Ni/CeO2, as can be seen in Figure 5c,d, which were acquired under the same conditions as those shown in Figure 5a,b. Figure 6a,b shows Ni/SiO2 at 400 °C in 4 Torr H2 and at 550 °C in 1 Torr C2H6, respectively. Several graphite layers formed on the surface of the Ni particle on SiO2 after 1/2 h. All Ni/SiO2 catalyst particles showed graphite formation. Figure 6c,d shows Ni/ CeO2 at 400 °C in 4 Torr H2 and at 550 °C in 1 Torr C2H6, respectively. Contrary to what was seen on Ni/SiO2, Ni/CeO2 showed no signs of graphite formation even after 4 h of C2H6

Figure 5. In situ C2H4 carbon deposition on Ni/SiO2 and Ni/CeO2. Images were acquired in H2 (a,c) to ensure that the catalyst was in the active Ni metal phase. Graphite was observed on the surface of Ni particles on both Ni/SiO2 (b) and Ni/CeO2 (d) when exposed to C2H4.

exposure. In Figure 6d, the crystalline CeO2 present in Figure 6c has become an amorphous CeO2−x phase. The representative structural change is shown in additional Ni/CeO2 regions in Figure S2. No structural changes were seen in Ni/CeO2 during C2H4 exposure, and the ceria support remained crystalline. The transformation from crystalline to amorphous ceria is thus facilitated by C2H6 exposure. It was hypothesized that this structural transformation was the result of oxygen being removed from the CeO2 lattice to inhibit graphite formation. To further test this hypothesis, in situ spectroscopy experiments were performed. In situ STEM experiments were conducted to probe local Ce oxidation states during C2H6 and C2H4 exposure at locations in the CeO2 cubes near Ni/CeO2 interfaces and at regions without any Ni particles nearby. Figure 7a shows a typical annular dark-field (ADF)-STEM image of the Ni/CeO2 catalyst. EELS line scans were acquired initially at 400 °C in 4 Torr H2 to use as a reference before hydrocarbon exposure. 1364

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Figure 8. (a) ADF-STEM image of Ni/CeO2 catalyst. Dotted line indicates EELS line scan. Red star indicates the position on the line scan where the insets were taken. (b) Energy-loss spectrum near Ni/ CeO2 interface (red star position) in 4 Torr H2 at 400 °C. (c) Energyloss spectrum near Ni/CeO2 interface (red star position) in 1 Torr C2H6 at 550 °C. Ce M45 edge intensity ratio changes during C2H6 exposure indicating a transition from Ce4+ to Ce3+.

Figure 6. In situ C2H6 carbon deposition on Ni/SiO2 and Ni/CeO2. Images were acquired in H2 (a,c) to ensure that the catalyst was in the active Ni metal phase. Graphite was observed on the surface of Ni particles on Ni/SiO2 (b) but not on Ni/CeO2 (d) when exposed to C2H6. The ceria support has become amorphous after C2H6 exposure (d).

intensity ratio change indicates a transition from Ce4+ to Ce3+ near the Ni/CeO2 interface. In each in situ STEM EELS experiment, EELS line scans were acquired from five to seven regions of interest in H2. Following hydrocarbon introduction, EELS line scans were acquired from the same regions that were observed in H2 exposure. An average Ce oxidation state as a function of distance from the Ni/CeO2 interface in H2, C2H4, and C2H6 was determined and is plotted in Figure 9. The Ce

Figure 7. (a) ADF-STEM image of the Ni/CeO2 catalyst. Dotted line indicates EELS line scan. Red star indicates the position on the line scan where (b) was acquired. (b) Energy-loss spectrum near Ni/CeO2 interface (red star position) in 0.5 Torr C2H4 at 550 °C. Little to no change of the Ce M45 edge intensity ratio was observed from the spectrum (not shown) acquired in 4 Torr H2 at 400 °C.

Figure 9. Plot of average Ce oxidation state as a function of distance from Ni/CeO2 interfaces in C2H6 and C2H4. EELS line scans were acquired from several regions of interest in each gas. The plot shows a slight reduction near the Ni/CeO2 interface during C2H4 exposure and a large reduction near the Ni/CeO2 interface during C2H6 exposure.

The line scans allowed the Ce oxidation state to be determined at each point along the line, thus providing spatially resolved information on oxidation state as a function of distance from the Ni/CeO2 interface. The dotted line in Figure 7a indicates the EELS line scan direction. Figure 7b is a typical spectrum from the EELS line scan near the Ni/CeO2 interface (indicated by the red star on the line scan) in C2H4. Little change was observed in the Ce M45 relative peak intensity ratio when C2H4 was introduced and the sample heated to 550 °C compared to spectra acquired in 4 Torr H2 at 400 °C, showing that the Ce near the metal-oxide interface was predominantly 4+. Figure 8a shows a representative ADF-STEM image of another Ni/CeO2 catalyst region. Figure 8b provides an energy-loss spectrum near the Ni/CeO2 interface where the catalyst is in 4 Torr H2 at 400 °C. A change in the Ce M45 relative peak intensity ratio is observed when 1 Torr C2H6 is introduced and the sample is heated to 550 °C as seen in Figure 8c. This Ce M45 peak

oxidation state remained near 4+ when the catalyst was in 4 Torr H2 at 400 °C as shown by the solid orange line. A slight reduction was observed near the Ni/CeO2 interface when in 1 Torr C2H4 at 550 °C as shown by the dashed blue line. A large change in Ce oxidation state (and thus oxygen removal) was seen at the Ni/CeO2 interface when exposed to 1 Torr C2H6 at 550 °C as evidenced by the dotted red line. Energy-loss spectra were also acquired at the surfaces and corners of bare CeO2 cubes (without Ni particles) in H2, C2H4, and C2H6, and the average Ce oxidation state in each gas was 4+. We conclude that the localized reduction zones near Ni/CeO2 interfaces are caused by a removal of oxygen during hydrocarbon exposure facilitated by the Ni particles. Furthermore, this evidence also 1365

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Figure 10. Schematic of carbon oxidation mechanism during C2H6 decomposition. (a) C2H6 is preferentially decomposed at the Ni/CeO2 interface, and atomic C and H are generated. (b) Oxygen from the CeO2 lattice oxidizes C and H. (c) H2O, CO2, and CO desorb from the CeO2 surface and leave behind oxygen vacancies.

suggests that the structural transformation observed in Figures 6d and S2 is related to oxygen deficiency in the ceria support.

but also leads to an increase in graphite-forming precursors that are strongly bound to Ni surfaces resulting in the graphite layers seen on Ni surfaces in Figure 5d. In contrast to the behavior of C2H4, the thermodynamically favorable location where decomposition of the C2H6 molecule will occur is near an oxidantin this case at Ni/CeO2 interface sites. At Ni/CeO2 interface sites, or Ni particle “perimeter” sites, Ni can catalyze the ODH reaction (C2H6 + 1/2 O2 → C2H4 + H2O) through the consumption of surface oxygen atoms in the CeO2 support due to its exothermic nature. The endothermic dehydrogenation reaction (C2H6 → C2H4 + H2) may still occur on Ni surfaces, albeit at a much slower rate than the ODH reaction route preferred at Ni perimeter sites. While the decomposition of C2H6 and C2H4 may both lead to graphite-forming precursors, facile C2H6 decomposition is restricted to Ni/CeO2 interface sites. Furthermore, graphiteforming precursors, such as C or C2, generated near the Ni/ CeO2 interface sites can then be oxidized with surface oxygen atoms from the ceria support to form CO or CO2, leaving behind oxygen vacancies. This mechanism is likely to inhibit carbon deposition on Ni/CeO2 during C2H6 exposure. For catalytic reforming processes where O2 is present (i.e., partial oxidation or autothermal reforming), surface vacancies can be filled by molecular oxygen and a Mars−van Krevelenlike carbon oxidation mechanism occurs, whereas surface vacancies on a SOFC anode are backfilled from bulk oxygen ion diffusion. In our in situ experiments, the O2 partial pressure is very low, and the primary source of oxygen was the CeO2 support (at least initially). Due to ceria’s high oxygen ion conductivity, oxygen atoms in the bulk can quickly migrate to backfill the vacancies left behind at the surface. As oxygen is continuously removed at the Ni/CeO2 interface, an oxygendepleted region is formed surrounding the Ni particle. The suggested carbon oxidation mechanism is supported by Figure 9, where it is shown that reduction of the CeO2 support occurs near Ni particles when exposed to C2H6. Furthermore, the structural changes seen in Figures 6d and S2 are also consistent with a loss of oxygen surrounding the Ni particle. The transition from crystalline CeO2 to an amorphous CeO2−x phase has also been observed in Ni/Pr-doped ceria due to a hydrogen spillover effect.64 Thus, we conclude that the lack of carbon on Ni/CeO2 during C2H6 exposure is due to the rapid removal of adsorbed decomposed hydrocarbon products, facilitated by a removal of oxygen from the CeO2 support. A schematic illustration highlighting the processes that occur during the carbon oxidation mechanism has been provided in Figure 10.

4. DISCUSSION Differences in the C2H6 and C2H4 molecules, as well as their molecular interactions with Ni/CeO2, contribute to the different carbon deposition behaviors observed in our experiments. C2H4 (ΔHf = +52 kJ/mol) is more thermodynamically unstable than C2H6 (ΔHf = −84 kJ/mol) and is more likely to readily decompose. The thermal dehydrogenation of ethylene to acetylene (C2H4 → C2H2 + H2) is an endothermic reaction (ΔH = 174 kJ/mol). However, once C2H2 is formed, subsequent decomposition reactions will occur rapidly to form carbon and hydrogen.39,52−54 Ethane’s thermal dehydrogenation to ethylene (C2H6 → C2H4 + H2) is also an endothermic reaction (ΔH = 136 kJ/mol).55,56 However, an alternative way to dehydrogenate C2H6 is through partial oxidation, otherwise known as oxidative dehydrogenation (ODH) (C2H6 + 1/2 O2 → C2H4 + H2O), which is exothermic (ΔH = −106 kJ/mol).57 Consequently, the dehydrogenation of C2H6 is thermodynamically favored in the presence of an oxidizing agent. During catalysis, the C−H bond is activated by a metal surface, in this case Ni.58,59 The rate limiting step of C2H6 decomposition on a Ni(111) surface is the initial C−H bond activation (Ea = 257.9 kJ/mol), whereas the initial C−H activation is more facile on Ni(111) for C2H4 decomposition (Ea = 47 kJ/mol).59−62 Compared to a C2H6 molecule, the C2H4 molecule’s relative instability and low C−H bond activation energy suggests that more rapid decomposition will take place directly on the Ni surface. If the rate at which carbon atoms accumulate on the Ni particle surface exceeds the rate at which carbon is removed from the surface, then the surplus carbon can arrange into graphene sheets and form graphite layers. Recent density functional theory (DFT) studies have examined C2H6 and C2H4 dehydrogenation reactions on Ni surfaces and examined each intermediate product; they concluded that binding energies (BE) exhibit the following trend: C2H6 < C2H4 < C2H2 < C2H < C2 < C.60,61,63 For example, the BE of C2H4 on Ni is 63 kJ/mol, whereas C2H2 is bound to the Ni surface with a BE of 251 kJ/mol. Carbon dimers (C2) are strongly bound to Ni with a BE of 708 kJ/mol and can be considered graphiteforming precursors. The formation of a carbon dimer (C2) from individual C atoms (C + C → C2) is an exothermic reaction (ΔH = −71 kJ/mol) on Ni, thus facilitating facile C− C bond formation and subsequent graphite formation.61,63 Therefore, C2H4 not only dissociates more rapidly than C2H6 1366

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ACS Applied Nano Materials



The carbon oxidation mechanism allows CeO2 to initially remove C2 H 4 decomposition products at the Ni/CeO2 interface. As adsorbed cracked hydrocarbon products from C 2 H 4 decomposition become oxidized at the Ni/CeO2 interface, the removal of oxygen causes the less pronounced reduction zone at the Ni/CeO2 interface seen in Figure 9. However, due to rapid C2H4 decomposition over the entire Ni surface and strongly bound carbon-containing decomposition products, graphite layer formation dominates and quickly covers the Ni particles. Once graphite layers have formed on the Ni particles, the ceria is unable to easily remove the carbon atoms (graphite is the low energy state of carbon), and the loss of oxygen from the ceria support is stopped, thus halting Ce oxidation state change and preserving the crystalline structure. The resulting Ni particles are encapsulated in graphite layers and have a crystalline CeO2 support that exhibits slight reduction zones near Ni/CeO2 interfaces. Both Figures 5d and 9 support these conclusions by showing graphite layers on Ni/ CeO2 and a slight reduction in Ce oxidation state near Ni/ CeO2 interfaces during C2H4 exposure. To summarize, chemisorbed C2H4 will be present in both gases, but it is located at different places on the catalysts. For the reactions in C2H4 gas, the chemisorbed C2H4 will be on the Ni metal surface where rapid dehydrogenation will lead to carbon formation. For reactions in C2H6 gas, most of the chemisorbed C2H4 will be located at the metal-oxide interface, since this is where oxidative dehydrogenation occurs. In this case, the oxide provides a supply of oxygen that can then be used to oxidize the subsequent C2H4 dehydrogenation products.

AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. ORCID

Ethan L. Lawrence: 0000-0003-0069-6709 Peter A. Crozier: 0000-0002-1837-2481 Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS We gratefully acknowledge support from NSF DMR-1308085 and ASU’s John M. Cowley Center for High Resolution Electron Microscopy. The authors would like to thank Joshua Vincent for helpful discussions.



REFERENCES

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5. CONCLUSION In situ ETEM techniques revealed the atomic-level three-phase interactions occurring at the metal−support interface during carbon deposition from light hydrocarbons over model Ni/ CeO2 and Ni/SiO2 catalysts. Structural and chemical interfacial changes occurring during species-dependent carbon deposition were determined using atomic-level imaging and electron energy-loss spectroscopy. No carbon deposition occurred during C2H6 exposure, and localized reduction zones formed at the Ni/CeO2 interface through a carbon oxidation mechanism. In contrast, less pronounced reduction zones occurred during C2H4 exposure, and carbon deposition occurred on Ni surfaces. Rapid dehydrogenation and subsequent graphite formation occurred on Ni surfaces during C2H4 exposure, whereas the metal−support interface catalyzed the oxidative dehydrogenation of C2H6 and oxidized the resulting carbonaceous species during C2H6 exposure. These experiments demonstrate that the ability of the interfacial sites on Ni/CeO2 to inhibit carbon deposition during reforming is strongly influenced by thermodynamic and kinetic considerations, which may show significant variation among different hydrocarbon species.



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The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsanm.8b00102. Temperature-programmed oxidation results from four different carbon-containing gases on an Ni/GDC catalyst; effect of C2H6 exposure on CeO2 structure (PDF) 1367

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